KR960003201B1 - Trip control device for circuit breaker - Google Patents

Abstract

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Description

Abnormal voltage detection control device

1 is a block diagram of an embodiment of the present invention.

Figure 2 is a waveform diagram for explaining the operation of one embodiment of the present invention.

3 is a circuit diagram of a conventional abnormal voltage detection control device.

* Explanation of symbols for main parts of the drawings

1: control power 3: drive circuit

4: electromagnetic coil 11: first voltage detector

12: second voltage detector 13: or gate

14: transistor V ₀ : control voltage

V ₁ : first voltage V ₂ : second voltage

T1, T2: Off signal T: Trip signal

The present invention relates to, for example, an abnormal voltage detection control device capable of selectively inserting a circuit breaker for protecting a power supply and a load. In particular, the control voltage such as a power supply voltage is an abnormality caused by an overvoltage. Value, the abnormal voltage detection control device which makes the breaker impossible to input.

In general, a circuit breaker capable of arbitrarily setting input and trips is inserted between a feeder system such as a generator and a load. The circuit breaker of this type is enabled by excitation of the electromagnetic coil in the abnormal voltage detection control device. When the control voltage from the power supply system is in the normal region, the electromagnetic coil is biased and abnormal. When in the area, the electromagnetic coil is rinsed and cannot be inserted. Therefore, when an abnormal voltage of the power feeding system is detected, the breaker is forcibly tripped to protect the generator and the load.

3 is a circuit diagram of a conventional abnormal voltage detection control apparatus described in Japanese Unexamined Patent Application Publication No. 58 (1983) -18441, for example, when an undervoltage due to a power supply voltage drop is detected, the electronic coil is swept to trip the breaker. The case where control is performed is shown.

In the figure, reference numeral 1 denotes a control power supply such as a generator that outputs an AC voltage. (2) is a rectifier for full-wave rectifying the AC voltage from the control power supply 1, and it is comprised by the diode bridge, the negative pole is grounded, and the plus pole is the control voltage V to each circuit element mentioned later. _It is a control power supply for applying _zero .

(3) is a PNP type transistor composed of a drive circuit of an electromagnetic coil (to be described later), and the emitter is connected to the positive pole of the rectifier 2. (4) is an electromagnetic coil connected in series to the collector of the transistor 3, one end of which is grounded, and is urged and annealed by turning the transistor 3 on and off.

In this case, the electromagnetic coil 4 is swept (falled) when the control voltage V ₀ indicates an undervoltage so that the circuit breaker (not shown) is tripped.

(5) denotes an N gate die Lister (hereinafter referred to as PUT) whose cathode is grounded, R1 denotes a resistor inserted between the anode of the PUT (5) and the positive electrode, and (6) denotes the cathode of the PUT (5). Zener diode inserted between the anode.

R2 and R3 are voltage divider resistors inserted between the plus and minus poles (ground), one resistor R3 consists of a variable resistor, and the connection point of each resistor, that is, the voltage divider point A, is connected to the gate of the PUT 5. It is.

(7) is a P gate die Lister (hereafter simply referred to as a die lister) with a cathode grounded, R4 is a resistor inserted between the anode of the die lister 7 and the positive pole, (8) PUT (5) And a capacitor inserted between the respective anodes of the thyristor 7, and 9 is a zener diode connected to the gate of the thyristor 7.

R5 and R6 are voltage divider resistors inserted between the positive pole and ground, one resistor R6 is formed of a variable resistor, and the voltage divider point B is connected to the cathode of the zener diode 9.

R7 is a resistor inserted between the anode of the die Lister 7 and the base of the transistor 3, the transistor 3 is turned on and off in accordance with the on and off of the die lister 7, the electromagnetic coil (4) ) Are subject to taxation and taxation.

As described above, the circuit breaker associated with the electromagnetic coil 4 can be input during the biasing of the electromagnetic coil 4 and cannot be inserted during the sausage of the electromagnetic coil 4.

Next, the operation of the conventional abnormal voltage detection control device shown in FIG. 3 will be described.

First, since the thyristor 7 is turned off during the power supply of the control power supply 1, the base potential of the transistor 3 is at the H level, and the transistor 3 is turned off. I'm tripping.

Now, when the control power supply 1 is sound and the control voltage V ₀ rises to the predetermined voltage of the minimum excitation level, the potential at the voltage dividing point B becomes higher than the zener voltage, and the zener diode 9 conducts and the thyristors 7 Is on.

Accordingly, the base potential of the transistor 3 becomes L level through the resistor R7, the transistor 3 is turned on, and the electromagnetic coil 4 is biased to become a suction state by the electromagnet, that is, a chargeable state. The voltage corresponding to the minimum excitation level at this time is arbitrarily set by adjusting the variable resistor R6 to change the potential of the voltage dividing point B.

In addition, the thyristor 7 is turned on, and the PUT 5 is forcibly turned off due to the current in the capacitor 8, and in this state, the control voltage V ₀ after the electromagnetic coil 4 is biased. Is maintained until the undervoltage is detected.

When the control voltage V ₀ falls and becomes below the minimum excitation level, the potential of the voltage dividing point A, which becomes the gate voltage of the PUT 5, becomes lower than the voltage of the zener diode 6, that is, the anode voltage of the PUT 5. 5) is turned on, and the electric charge of the condenser 8 currents the thyristor 7 to turn off the thyristor 7. Therefore, the transistor 3 is turned off, so that the electromagnetic coil 4 is cleaned (released), and the circuit breaker is tripped and cannot be inserted.

The minimum excitation level in the case of tripping operation due to undervoltage is set to have a hysteresis in order to stabilize the operation and lower than the voltage level when the electromagnetic coil 4 is biased.

When the control voltage V ₀ rises again to the minimum excitation possible excitation level, the electromagnetic coil 4 is biased as described above.

The conventional abnormal voltage detection control device trips the control target only when it detects that the control voltage V ₀ is undervoltage as described above. Therefore, the overvoltage exceeding the maximum allowable level is exceeded due to a misconnection of the control power supply 1. When applied as an input, the breaker does not trip and becomes a state capable of being inserted. Therefore, depending on the load connected to the circuit breaker, there is a problem of destroying expensive equipment or causing a serious accident such as a fire.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and by using a single electronic coil, an abnormal voltage detection control apparatus for tripping the control target not only at the time of undervoltage detection but also at the time of overvoltage detection above the maximum allowable level is obtained. For the purpose of

The abnormal voltage detection control device according to claim 1 of the present invention includes an electronic coil which is energized when the control voltage exceeds a minimum excitation level and enables the control object to be input, a drive circuit for selectively biasing and sintering the electronic coil; And a voltage detecting means for turning off the drive circuit when the control voltage exceeds the maximum allowable level and turning on the drive circuit when the control voltage drops from the maximum allowable level to the recoverable level.

In addition, the abnormal voltage detection control apparatus according to claim 2 of the present invention includes a first voltage detector for detecting a first voltage corresponding to a maximum allowable level by the voltage detection means, and a second voltage corresponding to a recoverable level. And a logic circuit for turning on and off the drive circuit by taking a logical sum of the second voltage detector, the output signals of the first voltage detector and the second voltage detector, and when the first voltage detector exceeds the first voltage. Outputs a logic 1 off signal, the second voltage detector outputs a logic 1 off signal when the control voltage exceeds the second voltage, and at the same time, turns off the signal from the first voltage detector, When the voltage drops to two voltages, the off signal from the second voltage detector is stopped.

In the present invention, when the control voltage exceeds the maximum allowable level, the electronic coil is turned off to disable the control object, and when the control voltage falls to the recoverable level, the electronic coil is biased to enable the control object to be reinserted. do.

Example 1

Next, an embodiment of the present invention will be described with reference to the drawings. 1 is a configuration diagram of an embodiment of the present invention, and (1) to (4) are as described above.

The drive circuit 3 consists of the above-mentioned transistors, and selectively energizes and cleans the electromagnetic coil 4, and is conducting in the initial state of power supply. Therefore, the electromagnetic coil 4 is automatically boosted when the control voltage V ₀ exceeds the minimum excitation level, thereby making it possible to input the control object.

R10 is a resistor inserted in series with the control power supply 1, and may be omitted if it can be substituted by an impedance included in the control power supply 1.

R11 and R12 are voltage divider resistors inserted between the positive and negative poles, and one resistor R12 is a variable resistor. Similarly, R13 and R14 are voltage divider resistors inserted between the positive and negative poles, and one resistor R14 is a variable resistor.

The divided resistor R11, and the divided point C of R12 is a terminal for detecting a first voltage V ₁ corresponding to the maximum allowable level of the control voltage V _0, the partial pressure point D of the divided resistors R13 and R14 is a return of the control voltage V ₀ It becomes a terminal for detecting the second voltage V ₂ corresponding to the possible level.

Denoted at 11 is a first voltage detector for detecting the potential at the divided point C, and outputs a logic 1 off signal T1 when indicating that the control voltage V ₀ has exceeded the first voltage V ₁ .

Reference numeral 12 denotes a second voltage detector for detecting the potential at the voltage dividing point D, and outputs an off signal T2 of logic 1 when indicating that the control voltage V ₀ has exceeded the second voltage V ₂ .

The second voltage detector 12 stops the off-signal T2 as logic 0 when indicating that the control voltage V ₀ has fallen to the second voltage.

Numeral 13 denotes a logic circuit or an gate that turns on and off the drive circuit by taking a logical sum of the output signals of the first voltage detector 11 and the second voltage detector 12, and is at least one of the off signals T1 and T2. This generates a trip signal T for turning off the drive circuit 3.

Reference numeral 14 denotes an NPN transistor inserted between both ends of the variable resistor R12, the emitter is grounded, and the off signal T2 is applied to the base. Therefore, the transistor 14 conducts when the off signal T2 is logic 1, and stops the off signal T1 from the first voltage detector 11.

Reference numeral 15 denotes a capacitor inserted between both ends of the variable resistor R12, and prevents a sudden rise in the potential at the divided point C when the transistor 14 is turned off because the control voltage V ₀ is reduced to a recoverable level.

The voltage divider R11 to R14, each of the voltage detectors 11 and 12, the or gate 13, the transistor 14, and the capacitor 15 are driven by the drive circuit 3 when the control voltage V ₀ exceeds the maximum allowable level. Is turned off and the voltage detecting means for turning on the drive circuit 3 when the control voltage V ₀ falls from the maximum allowable level or more to the recoverable level is constituted.

Second and turning also off signal waveform for explaining a trip operation and the recovery operation of the drive circuit (3) by T1 and T2, V ₁ is the drive circuit 3 becomes conductive when that is the control voltage of the tubular you like, V ₂ is When the drive circuit 3 drips, i.e., the control voltage at light load, the point c is the operating voltage of the second voltage detector 12 at the time of tripping by the off signal T1, and the point d is the recovery voltage when the off signal T2 is stopped. Is the input voltage to the first voltage detector 11 in.

Next, the operation of one embodiment of the present invention shown in FIG. 1 will be described with reference to FIG.

In the power supply of the control power supply 1, the output signals of the voltage detectors 11 and 12 are logic 0, and since the off signals T1 and T2 are not generated, the trip signal T is not generated, and the drive circuit 3 Is conducting. Therefore, when the control voltage V ₀ exceeds the minimum excitation level, the electromagnetic coil 4 is biased to enable the breaker. Usually, the minimum excitation level is about 80% of the rated voltage in terms of the power supply voltage of the control power supply 1.

At this time, since the electromagnetic coil 4 has a predetermined impedance, considering the impedance of the control power supply 1, that is, a series circuit between the resistor R10 and the impedance of the electromagnetic coil 4, the divided voltages of both impedances are controlled voltages. It is as V ₀ is generated and applied to each of the divided resistors R11 and R12 and R13, and R14.

In addition, the divided voltage of the control voltage V ₀ obtained from the divided points C and D of each voltage divider is input to each of the voltage detectors 11 and 12 separately, and used for level detection of the control voltage V ₀ .

When the control voltage V ₀ is in the circuit breaker insertable region, since the control voltage V ₁ under normal load is below the maximum allowable level, the potential at the voltage dividing point C indicates that the control voltage V ₀ is equal to or less than the first voltage V ₁ . Therefore, the output signals of each of the voltage detectors 11 and 12 are logic 0 together, and the trip signal T is not output from the or gate 13, and the electromagnetic coil 4 continues to be biased.

On the other hand, when the control voltage V ₀ rises and exceeds the first voltage V ₁ corresponding to the maximum allowable level, the potential at the divided point C represents the overvoltage of the control voltage V ₀ , so that the first voltage detector 11 Generate an off signal T1 of logic one. This off-signal T1 becomes the trip signal T through the or gate 13, trips the drive circuit 3, and cleans the electromagnetic coil 4 so that the breaker cannot be closed.

The first voltage V ₁ corresponding to the maximum allowable level is, for example, about 125% of the rated voltage when converted into a power supply voltage, and the potential at the voltage dividing point C corresponding to the first voltage V ₁ is applied to the variable resistor R12. Is set.

When the drive circuit 3 is turned off by the detection of the overvoltage, the control voltage V ₀ becomes the control voltage V ₂ at light load, and thus rises at once toward the point c in FIG.

At this time, at the point c just before the increase of the control voltage V ₀ is completed, since the second voltage V ₂ corresponding to the recoverable level is exceeded, the second voltage detector 12 generates the off signal T2 of logic 1. .

The off signal T2 is input to the or gate 13 to maintain the trip signal T, and the transistor 14 is turned on to set the input voltage of the first voltage detector 11 to the negative pole level to generate the off signal T1. Stop it.

At this time, since the trip signal T has already been held by the off signal T2, the electromagnetic coil 4 remains in the released state. Thus, the trip signal T is claim is dependent upon the off signal T2 from the second voltage detector 12, the voltage detection means is switched to the return possible level detection mode of the control voltage V _0.

Thereafter, when the control voltage V _{2 at} light load drops to the second voltage V ₂ , the potential at the voltage dividing point D indicates a recoverable level, and the output signal of the second voltage detector 12 becomes logic 0 to turn off the signal T2. Is stopped. Therefore, the trip signal T becomes L level, the drive circuit 3 is turned on (conducted), and the electromagnetic coil 4 is biased to enable the breaker to be reinserted.

The second voltage V ₂ corresponding to the recoverable level is, for example, about 120% of the rated voltage in terms of the power supply voltage, and the potential at the voltage dividing point D corresponding to the second voltage V ₂ is applied to the variable resistor R14. Is set. Here, in order to ensure the stability of the trip operation and the return operation, the operating voltage of both has a hysteresis of 5%.

By the return operation of the drive circuit 3 and the electromagnetic coil 4, the control voltage V ₀ returns to the control voltage V ₁ at normal load and descends at once toward the point d in FIG.

At the same time, the transistor 14 is turned off so that the potential of the voltage dividing point C is applied to the first voltage detector 11. To indicate that the control voltage V ₀ is equal to or less than the first voltage V _1, the first voltage detector ( 11) no off signal T1 is generated.

The potential at the voltage dividing point C rises immediately after the transistor 14 is turned off, but a rise delay is caused by the capacitor 15. Therefore, if the rising delay time by the condenser 15 is set to the delay time during which the control voltage V ₀ falls to the control voltage V ₁ (point d) under normal load, the control voltage V ₀ is set at the point d. Since the potential of the voltage dividing point C is input to the first voltage detector 11, the input voltage of the first voltage detector 11 reaches the detection level and does not malfunction.

In this way, the voltage of the electromagnetic coil 4 and the impedance of the resistor R10 can be varied by load variation. Therefore, the level detection of the control voltage V ₀ can be performed with high accuracy without raising the cost.

In addition, the electromagnetic coil 4 is automatically released when the control voltage V ₀ falls below the minimum excitation level, so that the tripping operation of the minimum excitation level can also be performed.

When the trip voltage is detected by the detection of the first voltage V ₁ , the control voltage V ₀ rises to the control voltage V ₂ at light load in a single step, so that the setting of the second voltage V ₂ is facilitated, and the drive circuit 3 and The electromagnetic coil 4 can be reliably operated.

In the above embodiment, the control power source 1 is an AC power source, but may be a DC power source.

In addition, although the control object which becomes input by the excitation of the electromagnetic coil 4 was made into the circuit breaker, it may be another control object which performs input and trip.

The electromagnetic coil 4 may be used as long as it has a predetermined impedance, and may be configured as, for example, an input transformer of a power supply device.

In addition, although the power supply system was used as the power supply system as it is, you may input through a transformer. In this case, since the impedance which a transformer has can be used as resistor R10, resistor R10 is abbreviate | omitted.

As described above, according to claim 1 of the present invention, the electronic coil which is energized when the control voltage exceeds the minimum excitation level and enables the control object to be input, the drive circuit which selectively biases and rinses the electronic coil, and the control voltage are A voltage detecting means for turning off the drive circuit when the maximum allowable level is exceeded and turning on the drive circuit when the control voltage falls from the maximum allowable level to the recoverable level; and the electronic coil when the control voltage exceeds the maximum allowable level. Since the control target cannot be inputted while the control voltage is reduced and the control voltage is reduced to the recoverable level, the electronic coil is forced to enable the control target to be reinserted, so that the abnormal voltage that can cause the control target to trip even when overvoltage is detected. There is an effect that a detection control device can be obtained.

Further, according to claim 2 of the present invention, the voltage detecting means includes a first voltage detector for detecting a first voltage corresponding to a maximum allowable level, a second voltage detector for detecting a second voltage corresponding to a recoverable level, It has a logic circuit that turns on and off the drive circuit by taking a logical sum of the output signals of the first voltage detector and the second voltage detector, and outputs a logic 1 off signal when the first voltage detector exceeds the first voltage. The second voltage detector outputs a logic 1 off signal when the control voltage exceeds the second voltage, stops the off signal from the first voltage detector, and when the control voltage falls to the second voltage. Since the OFF signal from the two voltage detectors is stopped, the abnormal voltage detection control device can be obtained to trip the control object with high accuracy even when overvoltage detection of the maximum allowable level or more is performed. And it is.

Claims (2)

When the applied control voltage exceeds the minimum excitation level, the electronic coil is energized to enable the control object to be injected, the drive circuit selectively biases and sinters the electronic coil, and the control voltage exceeds the maximum allowable level. A voltage detecting means for turning off the drive circuit and turning on the drive circuit when the control voltage drops from the maximum allowable level to a recoverable level, and the electronic coil if the control voltage exceeds the maximum allowable level. The control of abnormal voltage detection control apparatus is characterized in that the control target cannot be inputted by squeezing and the control target can be inputted by biasing the electromagnetic coil when the control voltage drops to the returnable level. 2. The apparatus of claim 1, wherein the voltage detecting means comprises: a first voltage detector for detecting a first voltage corresponding to the maximum allowable level; a second voltage detector for detecting a second voltage corresponding to the recoverable level; And a logic circuit for turning on and off the drive circuit by taking a logical sum of output signals of the first voltage detector and the second voltage detector, wherein the first voltage detector is configured to generate a logic when the control voltage exceeds the first voltage. Outputs an off signal of 1, the second voltage detector outputs an off signal of logic 1 when the control voltage exceeds the second voltage, and stops the off signal from the first voltage detector; And the off signal from the second voltage detector is stopped when a control voltage drops to the second voltage.